Patent Grant
11523644
This invention is in the field of thermally-insulating material. More particularly this invention relates to material that can be filled with thermally-insulating gas and to portable gas reservoirs and valve mechanisms for introducing gas into such material.
Thermal insulators have long been important for human survival and comfort in cold climates. The primary function of any thermal insulator is to reduce heat loss (that is, heat transfer from a heat source to a cold sink). Heat transfer can occur by convection, conduction, and radiation.
Heat loss through convective mixing of gases is caused by the tendency of a gas to form a rotational mixing pattern between a warmer (less dense) region and a cooler (more dense) region. In a convection cycle, warmer gas is constantly being exchanged for cooler gas. One of the primary ways thermal insulators work is by suppressing such convection by trapping or confining a volume of a gas within thermally-insulating material. For example, one reason a fiber-filled parka feels warm is that the air near the wearer's skin is warmed by body heat, and the fibers prevent or at least slow convective mixing of the warmed layer of air with the cold air outside.
Conduction involves heat flow through a material from hot to cold in the form of direct interaction of atoms and molecules. For example, the phenomenon of conduction is one of the reasons why a thin layer of insulation does not insulate as well as a thicker layer.
Radiation involves direct energy transfer between surfaces at different temperatures through infrared radiation. Such radiation can be suppressed by using infrared-reflective materials. For example, a glass surface of a vacuum flask is coated with silver to reflect infrared and thereby prevent heat transfer through the vacuum space between the glass walls.
Different thermal insulators prevent heat loss through convection, conduction, and radiation in different ways. For example, fiber-based thermal insulators like polyester fiber fill or fiberglass insulation use fibers of low thermal conductivity in a stack or batt with a volume of air trapped or confined amongst the fibers, thereby reducing convective heat transfer. Conduction is reduced by random orientation of the fibers across the stack or batt, and radiative heat loss is reduced because the radiation is scattered as it passes through the fibers.
A closed-cell structure such as foam or microsphere is another example of a thermal insulator. Closed-cell structures usually comprise a polymer matrix with many small, mostly closed cavities. As with fiber-based insulations, these insulators conserve heat by trapping a volume of air in and amongst the cells. In fact, convection is effectively eliminated inside the small, closed cells. Furthermore, conduction is reduced by using low conductivity materials, and radiation is low because the cells are typically very small and there is little temperature difference between cavity walls and hence low driving force for radiative heat transfer.
Thermal insulators present a tradeoff between effectiveness of insulation, bulk, and cost. For example, because of the bulkiness of fiber- or foam-based insulation, achieving a sufficient degree of insulation for a given set of conditions can be difficult without also making the article too bulky for practical use. Adding more fiber- or foam-based insulation inevitably adds weight. Such insulators are static in that the amount of insulation cannot be changed or adjusted as the user's needs change. For example, if a person is wearing a fiber-filled parka, or sleeping in a fiber filled sleeping bag, the amount of insulation cannot be increased or decreased as environmental conditions change or as the user's level of activity increases or decreases.
Also, processes of manufacturing many thermally-insulating materials produce toxic or environmentally damaging byproducts. For example, the manufacturing process for many thermal insulators such as polyester fibers or foams produces CFCs or greenhouse gases. Even worse, these thermal insulators continue to emit toxic chemicals long after their manufacture. For example, fiberglass insulation is typically manufactured with formaldehyde compounds that continue to outgas long after the insulation is placed in a wall or other structure. And many typical insulators, such as fiberglass or polyester fiber fill, produce loose fibers that can be harmful if they are inhaled.
The inventors believe they have discovered one or more of the disadvantages of thermally-insulating materials as briefly described above and a variety of novel aspects of thermally-insulating clothing that address these disadvantages and other features that may be utilized in other applications.
Briefly and in general terms, in one aspect an upper garment such as an inflatable jacket, vest, or shirt has one or more inflatable sections on its front side. In some embodiments, a plurality of such inflatable sections are interconnected by one or more inflatable air channels. These inflatable air channels in some instances extend across the back of the upper garment. One or more of the inflatable air channels may be adjacent or part of a neck-surrounding portion of the upper garment.
Some embodiments provide a small, lightweight, soft air pump that may comprise a compressible and expandable interior material having collapsible and expandable cavities through which air may be retained or expelled from the interior of the pump. For example, the interior material may be similar to a sponge. In its original (expanded) configuration, air fills the cavities, and when pressure is applied to compress the interior material, air is ejected from cavities into inflatable sections of the upper garment.
In some applications, a soft flexible container (sack) may surround or contain the interior material. This container may be made of relatively non-permeable fabric or other material such as a thin sheet of plastic. Compressing the container also compresses the interior material, pumping air out of the container.
In some instances, the container may have an opening, providing an air channel for air to pass into or out of the interior of the container. The opening may be located so that the a user can cover the opening with a portion of the hand, such as a finger for example, in order to cover the opening and prevent air from escaping the container during compression of the pump. The opening may thus provide a channel for air to enter the interior of the container when the user no longer block the opening.
In some embodiments, the container is connected to an air supply line that may have one or more sections, valves, control structures, and the like.
The container may located in differing locations on or within the garment, such as removably mounted within a conventional hand pocket or other pocket such as on an arm or adjacent a lower edge on the front side of the jacket. Differing locations can provide differing advantages such as explained in greater detail infra.
Other aspects will become apparent from the following exemplary description and drawings.
The preferred and other embodiments are disclosed in association with the following exemplary Figures and related Detailed Description.
In some embodiments the right inflatable section 104 includes a side pocket 116. The side pocket 116 may contain a hand pump (not shown), similar to the hand pump 112, for inflating the right inflatable section 104; in the embodiment shown, the side pocket 116 may be omitted or may serve as a utility pocket because only one pump is used for the entire garment.
The jacket 100 includes a neck section 118. In some embodiments an upper extremity 120 of the left inflatable section 102 extends around a left side of the neck section 118. Similarly, an upper extremity 122 of the right inflatable section 104 extends around a right side of the neck section 118.
An air release valve 124 may be provided, for example in the air tube 114 or as part of the hand pump 112. A user can operate the valve to release air from the inflatable sections.
Referring now to
In some embodiments the back side 128 may also include one or more inflatable sections that may be interconnected by air channels similar to the air channel 126 formed by the extremities 120 and 122 of the left and right inflatable sections 102 and 104. In the embodiment shown, the back side 128 does not include inflatable sections.
An air delivery channel 430 extends from the sack 428. A user-operable air release valve 432 may be provided in the air delivery channel 430 to enable the user to release air from the garment as desired. The valve 432 may also be configured as a one-way valve to prevent air from flowing back into the sack 428 from the garment. The air delivery channel 430 is connectable to an air tube such as the air tube 114 in
The sack 428 has first and second sides 434 and 436. The first side 434 of the sack 428 may have an air inlet 438 such as a finger-sized opening (between about 0.5 and 1.5 centimeters in diameter). A user may close the air inlet 438 by placing a finger tightly over it while applying hand pressure to the sack as a whole, for example by squeezing. When the air inlet 438 is closed and the sack 428 is squeezed, air is expelled from the material in the sack through the air delivery channel 430 and thence into the inflatable sections of the garment. When the user releases pressure on the sack and uncovers the air inlet 438, ambient air flows through the air inlet 438 into the material in the sack 428.
In some embodiments the soft air pump has dimensions of about 9 to 15 centimeters long by about 6 to 10 centimeters wide by about 1 to 2.5 centimeters thick. The soft air pump may weigh about 25 to 150 grams. The air channel 424 that extends around the back of the neck may be about 2 to 3 millimeters in diameter, uninflated.
A soft pump 814 similar to the soft pump 426 is connected to the air channels through an air release valve 816, an air tube 818, and a fitting 820. The soft pump includes a user-controllable air inlet 822 which may be a finger-sized opening as described above.
A hand pump such as the pump 112 or the pump 412, or a soft air pump such as the pump 426 or the pump 814, may be mounted in any convenient location on or in the garment together with an air tube such as the tube 114 or the tube 414 and a release valve such as the valve 124 or the valve 416. For example, the pump may be placed in a location where a part of a user's body other than a hand may activate the pump. As shown in
In some embodiments these components may be disposed in a pocket or near the lower edge of the garment. The sack of a soft pump may be secured in such a position by stitching, buttons, VELCRO®, a type of hook and loop fastener, or other fastening means, so that the user may merely grasp the sack or, in some instances, the surrounding garment at that location, and repeatedly squeeze the sack to pump air into the garment.
A simple flapper valve (not shown may be used to provide a one-way passage for air to flow from the pump 1002 into the garment 1000 when the air inlet 1006 is covered by a finger and the pump 1002 is squeezed. The flapper valve prevents backflow of air from the garment back into the pump 1002 when pressure is released; instead, when pressure on the pump 1002 is released, the pump fills with air drawn in through the air inlet 1006. The flapper valve may be included in a user-operable air release valve 1008 such that the user can release air from the garment by manually operating the air release valve and that the air release valve prevents air from leaving the garment except when the user operates the valve.
The soft pump 1002 may be located in any convenient part of the garment 1000. Depending on where the pump is located, the use may be able to inflate the garment by pressing a hand against the garment adjacent the sack, or squeezing an arm against a side of the garment, or the like. The soft pump 1002 may be connected to an inflatable section such as the left section 1004 of the garment through an air tube 1010, or the soft pump 1002 may connect directly to the inflatable section or even be disposed inside the inflatable section, eliminating any need for an air tube.
Any of the foregoing garments may be fabricated from any suitable fabric such as rayon, nylon, polyester, spandex, KEVLAR®, a type of para-aramid fiber, laminated KEVLAR®, or the like. Portions of the fabric that enclose the interconnected air channels may be bonded to a gas-impermeable material such as polyethylene, polypropylene, urethane, polyurethane, rubber, silicone rubber, latex rubber, butylrubber, MYLAR®, a type of “biaxially-oriented polyethylene terephephthalate,” polytetrafluoroethylene (PTFE), expanded PTFE, or the like.
Two sheets of gas-impermeable material may be joined together to form the interconnected air channels by such techniques as ultrasonic welding, laser welding, stamp heat welding, hot plate welding, gluing, taping, sewing, weaving, or one-piece weaving in a manner similar to that used to form airbags.
In some embodiments an air release valve such as the valves 124, 416, or 810 may located in a pocket or otherwise secured in a convenient position so a user may activate the valve to vent air from the garment by pressing or squeezing the valve.
In one embodiment, a method of use includes donning an inflatable garment similar to the ones described above and manipulating a pump provided with the garment to pump air into one or more inflatable sections of the garment. When the user wishes to remove the garment, the user may operate an air release valve provided with the garment to release air from the inflatable sections. If the garment is provided with a soft pump, the user may cover an air inlet with the user's finger or in some other way and then squeeze the pump, either by hand or with the user's arm or elbow depending on where in the garment the pump is disposed.
In some embodiments an inflatable cold-weather upper-body garment includes a plurality of interconnected gas flow chambers enclosed by gas-impermeable material within a portion of the garment and soft-sided means such as a soft pump of the kind described above, a squeeze bulb, or other suitable means for inflating the gas flow chambers with air by repeated applications of pressure by a user. The soft-sided means for inflating may be attached to an exterior surface of the garment, for example by being permanently sewn on, or detachably mounted by Velcro, or attached in some other suitable permanent or detachable way. The means for inflating may be disposed within a portion of the garment such as a sleeve or a side of a torso portion of the garment.
The foregoing description and the accompanying drawings illustrate principles of the invention by example but are not to be taken as limiting. The invention is limited only by the claims.
This application claims priority from U. S. Provisional Application Ser. No. 62/322,110 filed Apr. 13, 2016, the entire contents of which are incorporated herein by this reference.
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